Functionalization, Compatibilization and Properties of Polyolefin Composites with Natural Fibers

Pracellà, Mariano; Haque, Md. Minhaz‐Ul; Álvarez, Vera A.

doi:10.3390/polym2040554

Cited by 126 publications

(69 citation statements)

References 29 publications

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“…This leads to poor interface between organic filler and hydrophobic matrix of elastomer. In order to improve the interfacial interactions between rubber and organic filler, addition of compatibilizers is required [10], [11] in the case of maleated natural rubber (NR-g-AM). The compatibilizing agent was obtained by roll mixing NR with 5 phr (parts per 100 parts of rubber) of maleic anhydride for synthesis (produced by Merck KGaA, Germany, melting point 52°C) and 0,75 phr of Perkadox 40.…”

Section: Methodsmentioning

confidence: 99%

Studies on gamma irradiated rubber materials

Lungu

Stelescu

Cutrubinis

2018

IOP Conf. Ser.: Mater. Sci. Eng.

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Abstract. Due to the increase in use and production of polymer materials, there is a constant pressure of finding a solution to more environmental friendly composites. Beside the constant effort of recycling used materials, it seems more appropriate to manufacture and use biodegradable and renewable row materials. Natural polymers like starch, cellulose, lignin etc are ideal for preparing biodegradable composites. Some of the dynamic markets that use polymer materials are the food and pharmaceutical industries. Because of their desinfastation and sometimes sterility requirements, different treatment processes are applied, one of it being radiation treatment. The scope of this paper is to analyze the mechanical behaviour of rubber based materials irradiated with gamma rays at four medium doses, 30.1 kGy, 60.6 kGy, 91 kGy and 121.8 kGy. The objectives are the following: to identify the optimum radiation dose in order to obtain a good mechanical behaviour and to identify the mechanical behaviour of the material when adding different quantities of natural filler (20 phr, 60 phr and 100 phr).

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Section: Methodsmentioning

confidence: 99%

Studies on gamma irradiated rubber materials

Lungu

Stelescu

Cutrubinis

2018

IOP Conf. Ser.: Mater. Sci. Eng.

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“…The fiber was also used with other fibers such as jute, hemp and glass, sisal and flax [14][15][16][17]. However, the weak compatibility between fibers and polymer matrix due to their poor wettability and weak interfacial bonding, the low dispersion degree of the fibers, as well as its poor moisture resistance, generally leads to low performance materials, limiting their use [18]. Size, geometry and dispersion of filler particles in the matrix are other factors which can largely affect the composite properties.…”

Section: Introductionmentioning

confidence: 99%

“…Size, geometry and dispersion of filler particles in the matrix are other factors which can largely affect the composite properties. Surface modification of the fibers and/or polymer functionalization, as well as addition of compatibilizers is required in order to improve the interfacial interactions between hydrophobic polymer and hydrophilic fibers [18]. Therefore, to improve the fiber-matrix adhesion, a pretreatment of the fiber surface or the incorporation of surface modifier during processing is required.…”

Section: Introductionmentioning

confidence: 99%

Utilization of banana stalk fiber as reinforcement in low density polyethylene composite

Ogunsile

Oladeji

2016

Matéria (Rio J.)

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Natural fibers could serve as viable and abundant alternatives to the expensive and non -renewable synthetic fibers as reinforcement in thermoplastic composites. The potentiality of banana stalk fiber at reinforcing a low density polyethylene matrix was examined in this study. Fibers were extracted from the stalk of banana plant and characterized for its chemical composition and fiber contents. The fibers were modified by pulping with caustic soda to increase it wettability. The fiber dimension was measured using a binocular light microscope. FTIR spectra was used to identify the functional groups of modified and unmodified fibers. The composites were produced using a single -screw extruder, pelletized and then processed into test specimen samples by injection molding. The fiber volume in the polymer matrix was varied from 5.4 to 20 %. The effects of chemical treatment and increasing fiber content on the moisture absorption and mechanical properties of the composites were examined. The results showed that fiber of banana plant were characterized by medium to long fiber length (2.84 mm). The lignin content (7.99 %) was relatively low indicating a lower value of chemical consumption in the modification step. The SEM micrograph of the composite cross section showed good fiber/matrix interfacial bonding. The water absorption capacity of the composites increased with increase in fiber loading while the treated fibers showed a reduction in hydrophylicity of the composites. The treated fibers showed improved tensile strength and can thus be utilized in the production of composites with better properties

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“…The use of natural fibers for the reinforcement of composites has become a popular research topic due to natural fibers' availability and sustainability. Natural fiber has several advantageous properties such as good strength, low density, biodegradability and low cost of production (Ayrilmis et al, 2011;Pracella et al, 2010). Moreover, natural fiber-reinforced composites have a lower density than synthetic fiber-reinforced composites, which ensures the production of lighter composites (Akil et al, 2011;Leao et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Effect of Alkaline Treatment on the Properties of Oil Palm Empty Fruit Bunch Fiber-reinforced Polypropylene Composite

Fatra¹,

Rouhillahi²,

Helwani³

et al. 2016

IJTech

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Oil palm empty fruit bunch (OPEFB) is one of the waste products of oil palm plantations and has not been optimally used in Riau Province, Sumatera, Indonesia. OPEFB is reduced by incineration, which causes pollution problems. However, the combustion of OPEFB generates ash, which is rich in potassium. Moreover, OPEFB fiber has good strength, low cost, low density, and biodegradability, and it can be used as composite reinforcement. However, the natural fibers in composites have poor compatibility with the matrix and relatively high moisture absorption. Hydrolysis of OPEFB ash creates a base solution that can be utilized in an alkaline treatment process to increase the mechanical properties of natural composites. The aim of this study was to investigate the effect of various extracts of OPEFB ash on the tensile strength, flexural strength, and water absorption of an OPEFB fiber-polypropylene composite. The experimental design used was the Response Surface Method-Central Composite Design (RSM-CCD). The results showed that the tensile strength increased with an increase of fiber length and concentration of the OPEFB ash extract solution, but tensile strength decreased with a longer soaking time. Flexural strength increased with an increase in fiber length but decreased with an increase in the concentration of the OPEFB ash extract solution and longer soaking time. Water absorption increased with lower and higher concentrations of OPEFB ash extract solution and fiber length and with shorter and longer soaking times. The highest tensile strength (20.100 MPa) was achieved at 5%wt alkaline concentration, 36 h soaking time, and 3 cm fiber length. The highest flexural strength (30.216 MPa) was achieved at 5%wt alkaline concentration, 12 h soaking time, and 3 cm fiber length. The lowest water absorption (0.324%) was achieved at 10%wt alkaline concentration, 24 h soaking time, and 2 cm fiber length.

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Functionalization, Compatibilization and Properties of Polyolefin Composites with Natural Fibers

Cited by 126 publications

References 29 publications

Studies on gamma irradiated rubber materials

Studies on gamma irradiated rubber materials

Utilization of banana stalk fiber as reinforcement in low density polyethylene composite

Effect of Alkaline Treatment on the Properties of Oil Palm Empty Fruit Bunch Fiber-reinforced Polypropylene Composite

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